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package eu.hansolo.steelseries.gauges;
import eu.hansolo.steelseries.tools.ColorDef;
import eu.hansolo.steelseries.tools.CustomColorDef;
import eu.hansolo.steelseries.tools.LcdColor;
import eu.hansolo.steelseries.tools.NumberSystem;
import eu.hansolo.steelseries.tools.Orientation;
import eu.hansolo.steelseries.tools.Util;
import java.awt.event.ComponentEvent;
import java.awt.Container;
import java.awt.Dimension;
import java.awt.BasicStroke;
import java.awt.Paint;
import java.awt.Color;
import java.awt.Font;
import java.awt.Graphics2D;
import java.awt.LinearGradientPaint;
import java.awt.RenderingHints;
import java.awt.font.FontRenderContext;
import java.awt.font.TextLayout;
import java.awt.geom.AffineTransform;
import java.awt.Rectangle;
import java.awt.geom.GeneralPath;
import java.awt.geom.Point2D;
import java.awt.geom.Rectangle2D;
import java.awt.image.BufferedImage;
import java.awt.Transparency;
import java.awt.geom.Path2D;
import javax.swing.border.Border;
import org.pushingpixels.trident.Timeline;
import org.pushingpixels.trident.TimelineScenario;
import org.pushingpixels.trident.callback.TimelineCallback;
import org.pushingpixels.trident.ease.Sine;
import org.pushingpixels.trident.ease.Spline;
import org.pushingpixels.trident.ease.TimelineEase;
/**
*
* @author hansolo
*/
public abstract class AbstractLinear extends AbstractGauge implements Lcd {
//
private final Rectangle INNER_BOUNDS;
private final Rectangle FRAMELESS_BOUNDS;
// Bar related
private boolean startingFromZero;
private boolean transparentSectionsEnabled;
private boolean transparentAreasEnabled;
// LED related variables
private Point2D ledPosition;
// User LED related variables
private Point2D userLedPosition;
// LCD related variables
private String lcdUnitString;
private double lcdValue;
private String lcdInfoString;
protected static final Font LCD_STANDARD_FONT = new Font("Verdana", 0, 24);
protected static final Font LCD_DIGITAL_FONT = Util.INSTANCE.getDigitalFont().deriveFont(24);
private Timeline lcdTimeline;
// Animation related variables
private Timeline timeline;
private final TimelineEase STANDARD_EASING;
private final TimelineEase RETURN_TO_ZERO_EASING;
private TimelineCallback timelineCallback;
//
//
public AbstractLinear() {
super();
INNER_BOUNDS = new Rectangle(getPreferredSize());
FRAMELESS_BOUNDS = new Rectangle(getPreferredSize());
startingFromZero = false;
transparentSectionsEnabled = false;
transparentAreasEnabled = false;
ledPosition = new Point2D.Double((getInnerBounds().width - 18.0 - 16.0) / getInnerBounds().width, 0.453271028);
userLedPosition = new Point2D.Double(18.0 / getInnerBounds().width, 0.453271028);
lcdValue = 0;
lcdTimeline = new Timeline(this);
lcdUnitString = getUnitString();
lcdInfoString = "";
timeline = new Timeline(this);
STANDARD_EASING = new Spline(0.5f);
RETURN_TO_ZERO_EASING = new Sine();
addComponentListener(this);
}
//
//
/**
* Uses trident animation library to animate
* the setting of the value.
* The method plays a defined trident timeline
* that calls the setValue(double value) method
* with a given easing behaviour and duration.
* You should always use this method to set the
* gauge to a given value.
* @param VALUE
*/
public void setValueAnimated(final double VALUE) {
if (isEnabled()) {
if (timeline.getState() != Timeline.TimelineState.IDLE) {
timeline.abort();
}
final double TARGET_VALUE = VALUE < getMinValue() ? getMinValue() : (VALUE > getMaxValue() ? getMaxValue() : VALUE);
if (!isAutoResetToZero()) {
timeline.removeCallback(timelineCallback);
timeline = new Timeline(this);
timeline.addPropertyToInterpolate("value", getValue(), TARGET_VALUE);
timeline.setEase(STANDARD_EASING);
//TIMELINE.setDuration((long) (getStdTimeToValue() * fraction));
timeline.setDuration(getStdTimeToValue());
timelineCallback = new TimelineCallback() {
@Override
public void onTimelineStateChanged(final Timeline.TimelineState OLD_STATE,
final Timeline.TimelineState NEW_STATE,
final float OLD_VALUE, final float NEW_VALUE) {
if (NEW_STATE == Timeline.TimelineState.IDLE) {
repaint(getInnerBounds());
}
// Check if current value exceeds maxMeasuredValue
if (getValue() > getMaxMeasuredValue()) {
setMaxMeasuredValue(getValue());
}
}
@Override
public void onTimelinePulse(final float OLD_VALUE, final float NEW_VALUE) {
// Check if current value exceeds maxMeasuredValue
if (getValue() > getMaxMeasuredValue()) {
setMaxMeasuredValue(getValue());
}
// Check if current value exceeds minMeasuredValue
if (getValue() < getMinMeasuredValue()) {
setMinMeasuredValue(getValue());
}
}
};
timeline.addCallback(timelineCallback);
timeline.play();
} else {
final TimelineScenario AUTOZERO_SCENARIO = new TimelineScenario.Sequence();
final Timeline TIMELINE_TO_VALUE = new Timeline(this);
TIMELINE_TO_VALUE.addPropertyToInterpolate("value", getValue(), TARGET_VALUE);
TIMELINE_TO_VALUE.setEase(RETURN_TO_ZERO_EASING);
//TIMELINE_TO_VALUE.setDuration((long) (getRtzTimeToValue() * fraction));
TIMELINE_TO_VALUE.setDuration(getRtzTimeToValue());
TIMELINE_TO_VALUE.addCallback(new TimelineCallback() {
@Override
public void onTimelineStateChanged(Timeline.TimelineState oldState,
Timeline.TimelineState newState,
float oldValue, float newValue) {
if (oldState == Timeline.TimelineState.PLAYING_FORWARD && newState == Timeline.TimelineState.DONE) {
// Set the peak value and start the timer
getModel().setPeakValue(getValue());
getModel().setPeakValueVisible(true);
if (getPeakTimer().isRunning()) {
stopPeakTimer();
}
startPeakTimer();
// Check if current value exceeds maxMeasuredValue
if (getValue() > getMaxMeasuredValue()) {
setMaxMeasuredValue(getValue());
}
}
}
@Override
public void onTimelinePulse(float oldValue, float newValue) {
// Check if current value exceeds maxMeasuredValue
if (getValue() > getMaxMeasuredValue()) {
setMaxMeasuredValue(getValue());
}
// Check if current value exceeds minMeasuredValue
if (getValue() < getMinMeasuredValue()) {
setMinMeasuredValue(getValue());
}
}
});
final Timeline TIMELINE_TO_ZERO = new Timeline(this);
TIMELINE_TO_ZERO.addPropertyToInterpolate("value", TARGET_VALUE, 0.0);
TIMELINE_TO_ZERO.setEase(RETURN_TO_ZERO_EASING);
//TIMELINE_TO_ZERO.setDuration((long) (getRtzTimeBackToZero() * fraction));
TIMELINE_TO_ZERO.setDuration(getRtzTimeBackToZero());
AUTOZERO_SCENARIO.addScenarioActor(TIMELINE_TO_VALUE);
AUTOZERO_SCENARIO.addScenarioActor(TIMELINE_TO_ZERO);
// AUTOZERO_SCENARIO.addCallback(new org.pushingpixels.trident.callback.TimelineScenarioCallback()
// {
// @Override
// public void onTimelineScenarioDone()
// {
//
// }
// });
AUTOZERO_SCENARIO.play();
}
}
}
/**
* Returns the color of the bar
* @return the selected color of the bar
*/
public ColorDef getValueColor() {
return getModel().getValueColor();
}
/**
* Sets the color of the bar
* @param VALUE_COLOR
*/
public void setValueColor(final ColorDef VALUE_COLOR) {
getModel().setValueColor(VALUE_COLOR);
repaint(getInnerBounds());
}
/**
* Returns the object that represents holds the custom value color
* @return the object that represents the custom value color
*/
public CustomColorDef getCustomValueColorObject() {
return getModel().getCustomValueColorObject();
}
/**
* Returns the color of the bar from which the custom bar color will calculated
* @return the color of the bar from which the custom bar color will be calculated
*/
public Color getCustomValueColor() {
return getModel().getCustomValueColor();
}
/**
* Sets the color of the bar from which the custom bar color will be calculated
* @param COLOR
*/
public void setCustomValueColor(final Color COLOR) {
getModel().setCustomValueColorObject(new CustomColorDef(COLOR));
repaint(getInnerBounds());
}
/**
* Returns true if the bar/bargraph will always start from zero instead from
* the minValue. This could be useful if you would like to create something
* like a g-force meter, where 0 is in the center of the range and the bar
* could move in negative and positive direction. In combination with
* AutoReturnToZero this feature might be useful.
* @return true if the bar/bargraph will always start to in-/decrease from zero
*/
public boolean isStartingFromZero() {
return this.startingFromZero;
}
/**
* Enables/Disables the feature that the bar/bargraph will always start from zero
* instead from the minValue. This could be useful if you would like to create
* something like a g-force meter, where 0 is in the center of the range and
* the bar could move in negative and positive direction. In combination with
* AutoReturnToZero this feature might be useful.
* @param STARTING_FROM_ZERO
*/
public void setStartingFromZero(final boolean STARTING_FROM_ZERO) {
this.startingFromZero = STARTING_FROM_ZERO;
}
public int getMaxNoOfMinorTicks() {
return getModel().getMaxNoOfMinorTicks();
}
public void setMaxNoOfMinorTicks(final int MAX_NO_OF_MINOR_TICKS) {
getModel().setMaxNoOfMinorTicks(MAX_NO_OF_MINOR_TICKS);
init(getInnerBounds().width, getInnerBounds().height);
repaint(getInnerBounds());
}
public int getMaxNoOfMajorTicks() {
return getModel().getMaxNoOfMajorTicks();
}
public void setMaxNoOfMajorTicks(final int MAX_NO_OF_MAJOR_TICKS) {
getModel().setMaxNoOfMajorTicks(MAX_NO_OF_MAJOR_TICKS);
init(getInnerBounds().width, getInnerBounds().height);
repaint(getInnerBounds());
}
/**
* Returns the current position of the gauge threshold led
* @return the current position of the gauge threshold led
*/
@Override
public Point2D getLedPosition() {
return ledPosition;
}
/**
* Sets the position of the gauge threshold led to the given values
* @param X
* @param Y
*/
@Override
public void setLedPosition(final double X, final double Y) {
ledPosition.setLocation(X, Y);
repaint(getInnerBounds());
}
/**
* Sets the position of the gauge threshold led to the given values
* @param LED_POSITION
*/
public void setLedPosition(final Point2D LED_POSITION) {
ledPosition.setLocation(LED_POSITION);
repaint(getInnerBounds());
}
/**
* Returns the current position of the gauge user led
* @return the current position of the gauge user led
*/
@Override
public Point2D getUserLedPosition() {
return userLedPosition;
}
/**
* Sets the position of the gauge user led to the given values
* @param X
* @param Y
*/
@Override
public void setUserLedPosition(final double X, final double Y) {
userLedPosition.setLocation(X, Y);
repaint(getInnerBounds());
}
/**
* Sets the position of the gauge threshold led to the given values
* @param USER_LED_POSITION
*/
public void setUserLedPosition(final Point2D USER_LED_POSITION) {
userLedPosition.setLocation(USER_LED_POSITION);
repaint(getInnerBounds());
}
protected void createLedImages() {
if (getOrientation() == Orientation.VERTICAL) {
recreateLedImages(getWidth());
} else {
recreateLedImages(getHeight());
}
}
/**
* Returns the visibility of the lcd display
* @return true if the lcd display is visible
*/
public boolean isLcdVisible() {
return getModel().isLcdVisible();
}
/**
* Enables or disables the visibility of the lcd display
* @param LCD_VISIBLE
*/
public void setLcdVisible(final boolean LCD_VISIBLE) {
getModel().setLcdVisible(LCD_VISIBLE);
init(getInnerBounds().width, getInnerBounds().height);
repaint(getInnerBounds());
}
@Override
public boolean isValueCoupled() {
return getModel().isValueCoupled();
}
@Override
public void setValueCoupled(final boolean VALUE_COUPLED) {
getModel().setValueCoupled(VALUE_COUPLED);
repaint(getInnerBounds());
}
@Override
public double getLcdValue() {
return this.lcdValue;
}
@Override
public void setLcdValue(final double LCD_VALUE) {
this.lcdValue = LCD_VALUE;
repaint(getLcdBounds());
}
@Override
public void setLcdValueAnimated(final double LCD_VALUE) {
if (lcdTimeline.getState() == Timeline.TimelineState.PLAYING_FORWARD || lcdTimeline.getState() == Timeline.TimelineState.PLAYING_REVERSE) {
lcdTimeline.abort();
}
lcdTimeline = new Timeline(this);
lcdTimeline.addPropertyToInterpolate("lcdValue", this.lcdValue, LCD_VALUE);
lcdTimeline.setEase(new Spline(0.5f));
lcdTimeline.play();
}
@Override
public double getLcdThreshold() {
return getModel().getLcdThreshold();
}
@Override
public void setLcdThreshold(final double LCD_THRESHOLD) {
getModel().setLcdThreshold(LCD_THRESHOLD);
if (getModel().isLcdThresholdVisible()) {
repaint(getInnerBounds());
}
}
@Override
public boolean isLcdThresholdVisible() {
return getModel().isLcdThresholdVisible();
}
@Override
public void setLcdThresholdVisible(final boolean LCD_THRESHOLD_VISIBLE) {
getModel().setLcdThresholdVisible(LCD_THRESHOLD_VISIBLE);
repaint(getInnerBounds());
}
@Override
public boolean isLcdThresholdBehaviourInverted() {
return getModel().isLcdThresholdBehaviourInverted();
}
@Override
public void setLcdThresholdBehaviourInverted(final boolean LCD_THRESHOLD_BEHAVIOUR_INVERTED) {
getModel().setLcdThresholdBehaviourInverted(LCD_THRESHOLD_BEHAVIOUR_INVERTED);
repaint(getInnerBounds());
}
@Override
public String getLcdUnitString() {
return lcdUnitString;
}
@Override
public void setLcdUnitString(final String UNIT_STRING) {
this.lcdUnitString = UNIT_STRING;
init(getInnerBounds().width, getInnerBounds().height);
repaint(getInnerBounds());
}
@Override
public boolean isLcdUnitStringVisible() {
return getModel().isLcdUnitStringVisible();
}
@Override
public void setLcdUnitStringVisible(final boolean UNIT_STRING_VISIBLE) {
getModel().setLcdUnitStringVisible(UNIT_STRING_VISIBLE);
init(getInnerBounds().width, getInnerBounds().height);
repaint(getInnerBounds());
}
@Override
public boolean isDigitalFont() {
return getModel().isDigitalFontEnabled();
}
@Override
public void setDigitalFont(final boolean DIGITAL_FONT) {
getModel().setDigitalFontEnabled(DIGITAL_FONT);
init(getInnerBounds().width, getInnerBounds().height);
repaint(getInnerBounds());
}
@Override
public boolean isCustomLcdUnitFontEnabled() {
return getModel().isCustomLcdUnitFontEnabled();
}
@Override
public void setCustomLcdUnitFontEnabled(final boolean USE_CUSTOM_LCD_UNIT_FONT) {
getModel().setCustomLcdUnitFontEnabled(USE_CUSTOM_LCD_UNIT_FONT);
repaint(getInnerBounds());
}
@Override
public Font getCustomLcdUnitFont() {
return getModel().getCustomLcdUnitFont();
}
@Override
public void setCustomLcdUnitFont(final Font CUSTOM_LCD_UNIT_FONT) {
getModel().setCustomLcdUnitFont(CUSTOM_LCD_UNIT_FONT);
init(getInnerBounds().width, getInnerBounds().height);
repaint(getInnerBounds());
}
@Override
public int getLcdDecimals() {
return getModel().getLcdDecimals();
}
@Override
public void setLcdDecimals(final int DECIMALS) {
getModel().setLcdDecimals(DECIMALS);
repaint(getInnerBounds());
}
@Override
public LcdColor getLcdColor() {
return getModel().getLcdColor();
}
@Override
public void setLcdColor(final LcdColor COLOR) {
getModel().setLcdColor(COLOR);
init(getInnerBounds().width, getInnerBounds().height);
repaint(getInnerBounds());
}
@Override
public Paint getCustomLcdBackground() {
return getModel().getCustomLcdBackground();
}
@Override
public void setCustomLcdBackground(final Paint CUSTOM_LCD_BACKGROUND) {
getModel().setCustomLcdBackground(CUSTOM_LCD_BACKGROUND);
init(getInnerBounds().width, getInnerBounds().height);
repaint(getInnerBounds());
}
@Override
public Color getCustomLcdForeground() {
return getModel().getCustomLcdForeground();
}
@Override
public void setCustomLcdForeground(final Color CUSTOM_LCD_FOREGROUND) {
getModel().setCustomLcdForeground(CUSTOM_LCD_FOREGROUND);
init(getInnerBounds().width, getInnerBounds().height);
repaint(getInnerBounds());
}
@Override
public String formatLcdValue(final double VALUE) {
final StringBuilder DEC_BUFFER = new StringBuilder(16);
DEC_BUFFER.append("0");
if (getModel().getLcdDecimals() > 0) {
DEC_BUFFER.append(".");
}
for (int i = 0; i < getModel().getLcdDecimals(); i++) {
DEC_BUFFER.append("0");
}
if (getModel().isLcdScientificFormatEnabled()) {
DEC_BUFFER.append("E0");
}
DEC_BUFFER.trimToSize();
final java.text.DecimalFormat DEC_FORMAT = new java.text.DecimalFormat(DEC_BUFFER.toString(), new java.text.DecimalFormatSymbols(java.util.Locale.US));
return DEC_FORMAT.format(VALUE);
}
@Override
public boolean isLcdScientificFormat() {
return getModel().isLcdScientificFormatEnabled();
}
@Override
public void setLcdScientificFormat(boolean LCD_SCIENTIFIC_FORMAT) {
getModel().setLcdScientificFormatEnabled(LCD_SCIENTIFIC_FORMAT);
repaint(getInnerBounds());
}
@Override
public Font getLcdValueFont() {
return getModel().getLcdValueFont();
}
@Override
public void setLcdValueFont(final Font LCD_VALUE_FONT) {
getModel().setLcdValueFont(LCD_VALUE_FONT);
repaint(getInnerBounds());
}
@Override
public Font getLcdUnitFont() {
return getModel().getLcdUnitFont();
}
@Override
public void setLcdUnitFont(final Font LCD_UNIT_FONT) {
getModel().setLcdUnitFont(LCD_UNIT_FONT);
repaint(getInnerBounds());
}
@Override
public Font getLcdInfoFont() {
return getModel().getLcdInfoFont();
}
@Override
public void setLcdInfoFont(final Font LCD_INFO_FONT) {
getModel().setLcdInfoFont(LCD_INFO_FONT);
repaint(getInnerBounds());
}
@Override
public String getLcdInfoString() {
return lcdInfoString;
}
@Override
public void setLcdInfoString(final String LCD_INFO_STRING) {
lcdInfoString = LCD_INFO_STRING;
repaint(getInnerBounds());
}
@Override
public NumberSystem getLcdNumberSystem() {
return getModel().getNumberSystem();
}
@Override
public void setLcdNumberSystem(final NumberSystem NUMBER_SYSTEM) {
getModel().setNumberSystem(NUMBER_SYSTEM);
switch (NUMBER_SYSTEM) {
case HEX:
lcdInfoString = "hex";
break;
case OCT:
lcdInfoString = "oct";
break;
case DEC:
default:
lcdInfoString = "";
break;
}
repaint(getInnerBounds());
}
@Override
public abstract Rectangle getLcdBounds();
@Override
public void toggleDesign() {
if (getActiveDesign().equals(getDesign1())) {
setActiveDesign(getDesign2());
} else {
setActiveDesign(getDesign1());
}
}
/**
* Returns true if the glow indicator is visible
* @return true if the glow indicator is visible
*/
@Override
public boolean isGlowVisible() {
return getModel().isGlowVisible();
}
/**
* Enables / disables the glow indicator
* @param GLOW_VISIBLE
*/
public void setGlowVisible(final boolean GLOW_VISIBLE) {
getModel().setGlowVisible(GLOW_VISIBLE);
init(getInnerBounds().width, getInnerBounds().height);
repaint(getInnerBounds());
}
/**
* Returns the color that will be used for the glow indicator
* @return the color that will be used for the glow indicator
*/
public Color getGlowColor() {
return getModel().getGlowColor();
}
/**
* Sets the color that will be used for the glow indicator
* @param GLOW_COLOR
*/
public void setGlowColor(final Color GLOW_COLOR) {
getModel().setGlowColor(GLOW_COLOR);
init(getInnerBounds().width, getInnerBounds().height);
repaint(getInnerBounds());
}
/**
* Returns true if the glow indicator is glowing
* @return true if the glow indicator is glowing
*/
public boolean isGlowing() {
return getModel().isGlowing();
}
/**
* Enables / disables the glowing of the glow indicator
* @param GLOWING
*/
public void setGlowing(final boolean GLOWING) {
getModel().setGlowing(GLOWING);
repaint(getInnerBounds());
}
/**
* Returns the color of the small outer frame of the gauge
* @return the color of the small outer frame of the gauge
*/
public Paint getOuterFrameColor() {
return FRAME_FACTORY.getOuterFrameColor();
}
/**
* Sets the color of the small outer frame of the gauge
* @param OUTER_FRAME_COLOR
*/
public void setOuterFrameColor(final Paint OUTER_FRAME_COLOR) {
FRAME_FACTORY.setOuterFrameColor(OUTER_FRAME_COLOR);
init(getInnerBounds().width, getInnerBounds().height);
repaint(getInnerBounds());
}
/**
* Returns the color of the small inner frame of the gauge
* @return the color of the small inner frame of the gauge
*/
public Paint getInnerFrameColor() {
return FRAME_FACTORY.getInnerFrameColor();
}
/**
* Sets the color of the small inner frame of the gauge
* @param INNER_FRAME_COLOR
*/
public void setInnerFrameColor(final Paint INNER_FRAME_COLOR) {
FRAME_FACTORY.setInnerFrameColor(INNER_FRAME_COLOR);
init(getInnerBounds().width, getInnerBounds().height);
repaint(getInnerBounds());
}
/**
* Returns true if the sections will be filled with a transparent color
* @return true if the sections will be filled with a transparent color
*/
public boolean isTransparentSectionsEnabled() {
return transparentSectionsEnabled;
}
/**
* Enables / disables the usage of a transparent color for filling sections
* @param TRANSPARENT_SECTIONS_ENABLED
*/
public void setTransparentSectionsEnabled(final boolean TRANSPARENT_SECTIONS_ENABLED) {
transparentSectionsEnabled = TRANSPARENT_SECTIONS_ENABLED;
init(getInnerBounds().width, getInnerBounds().height);
repaint(getInnerBounds());
}
/**
* Returns true if the areas will be filled with a transparent color
* @return true if the areas will be filled with a transparent color
*/
public boolean isTransparentAreasEnabled() {
return transparentAreasEnabled;
}
/**
* Enables / disables the usage of a transparent color for filling areas
* @param TRANSPARENT_AREAS_ENABLED
*/
public void setTransparentAreasEnabled(final boolean TRANSPARENT_AREAS_ENABLED) {
transparentAreasEnabled = TRANSPARENT_AREAS_ENABLED;
init(getInnerBounds().width, getInnerBounds().height);
repaint(getInnerBounds());
}
//
//
/**
* Returns the frame image with the currently active framedesign
* with the given with and height.
* @param WIDTH
* @param HEIGHT
* @return buffered image containing the frame in the active frame design
*/
protected BufferedImage create_FRAME_Image(final int WIDTH, final int HEIGHT) {
return FRAME_FACTORY.createLinearFrame(WIDTH, HEIGHT, getFrameDesign(), getCustomFrameDesign(), getFrameEffect());
}
/**
* Returns the frame image with the currently active framedesign
* with the given with and height.
* @param WIDTH
* @param HEIGHT
* @param IMAGE
* @return buffered image containing the frame in the active frame design
*/
protected BufferedImage create_FRAME_Image(final int WIDTH, final int HEIGHT, final BufferedImage IMAGE) {
return FRAME_FACTORY.createLinearFrame(WIDTH, HEIGHT, getFrameDesign(), getCustomFrameDesign(), getFrameBaseColor(), isFrameBaseColorEnabled(), getFrameEffect(), IMAGE);
}
/**
* Returns the background image with the currently active backgroundcolor
* with the given width and height.
* @param WIDTH
* @param HEIGHT
* @return buffered image containing the background with the selected background design
*/
protected BufferedImage create_BACKGROUND_Image(final int WIDTH, final int HEIGHT) {
return create_BACKGROUND_Image(WIDTH, HEIGHT, null);
}
/**
* Returns the background image with the currently active backgroundcolor
* with the given width and height.
* @param WIDTH
* @param HEIGHT
* @param image
* @return buffered image containing the background with the selected background design
*/
protected BufferedImage create_BACKGROUND_Image(final int WIDTH, final int HEIGHT, BufferedImage image) {
if (WIDTH <= 0 || HEIGHT <= 0) {
return UTIL.createImage(1, 1, Transparency.TRANSLUCENT);
}
if (image == null) {
image = UTIL.createImage(WIDTH, HEIGHT, Transparency.TRANSLUCENT);
}
final Graphics2D G2 = image.createGraphics();
G2.setRenderingHint(RenderingHints.KEY_ANTIALIASING, RenderingHints.VALUE_ANTIALIAS_ON);
G2.setRenderingHint(RenderingHints.KEY_STROKE_CONTROL, RenderingHints.VALUE_STROKE_NORMALIZE);
final int IMAGE_WIDTH = image.getWidth();
final int IMAGE_HEIGHT = image.getHeight();
// Draw the background image
BACKGROUND_FACTORY.createLinearBackground(WIDTH, HEIGHT, getBackgroundColor(), getModel().getCustomBackground(), getModel().getTextureColor(), image);
// Draw the custom layer if selected
if (isCustomLayerVisible()) {
G2.drawImage(UTIL.getScaledInstance(getCustomLayer(), IMAGE_WIDTH, IMAGE_HEIGHT, RenderingHints.VALUE_INTERPOLATION_BICUBIC), 0, 0, null);
}
G2.dispose();
return image;
}
/**
* Returns an image that simulates a glowing ring which could be used to visualize
* a state of the gauge by a color. The LED might be too small if you are not in front
* of the screen and so one could see the current state more easy.
* @param WIDTH
* @param HEIGHT
* @param GLOW_COLOR
* @param ON
* @return an image that simulates a glowing ring
*/
protected BufferedImage create_GLOW_Image(final int WIDTH, final int HEIGHT, final Color GLOW_COLOR, final boolean ON) {
return GLOW_FACTORY.createLinearGlow(WIDTH, HEIGHT, GLOW_COLOR, ON);
}
/**
* Returns the track image with the given values.
* @param WIDTH
* @param HEIGHT
* @param MIN_VALUE
* @param MAX_VALUE
* @param TRACK_START
* @param TRACK_SECTION
* @param TRACK_STOP
* @param TRACK_START_COLOR
* @param TRACK_SECTION_COLOR
* @param TRACK_STOP_COLOR
* @return a buffered image of the track colored with the given values
*/
protected BufferedImage create_TRACK_Image(final int WIDTH, final int HEIGHT, final double MIN_VALUE,
final double MAX_VALUE, final double TRACK_START,
final double TRACK_SECTION, final double TRACK_STOP,
final Color TRACK_START_COLOR,
final Color TRACK_SECTION_COLOR,
final Color TRACK_STOP_COLOR) {
return create_TRACK_Image(WIDTH, HEIGHT, MIN_VALUE, MAX_VALUE, TRACK_START, TRACK_SECTION, TRACK_STOP, TRACK_START_COLOR, TRACK_SECTION_COLOR, TRACK_STOP_COLOR, null);
}
/**
* Returns the track image with the given values.
* @param WIDTH
* @param HEIGHT
* @param MIN_VALUE
* @param MAX_VALUE
* @param TRACK_START
* @param TRACK_SECTION
* @param TRACK_STOP
* @param TRACK_START_COLOR
* @param TRACK_SECTION_COLOR
* @param TRACK_STOP_COLOR
* @param image
* @return a buffered image of the track colored with the given values
*/
protected BufferedImage create_TRACK_Image(final int WIDTH, final int HEIGHT, final double MIN_VALUE,
final double MAX_VALUE, final double TRACK_START,
final double TRACK_SECTION, final double TRACK_STOP,
final Color TRACK_START_COLOR,
final Color TRACK_SECTION_COLOR,
final Color TRACK_STOP_COLOR,
BufferedImage image) {
if (WIDTH <= 0 || HEIGHT <= 0) {
return UTIL.createImage(1, 1, Transparency.TRANSLUCENT);
}
if (TRACK_STOP > MAX_VALUE) {
throw new IllegalArgumentException("Please adjust track start and/or track stop values");
}
if (image == null) {
image = UTIL.createImage(WIDTH, HEIGHT, Transparency.TRANSLUCENT);
}
final Graphics2D G2 = image.createGraphics();
G2.setRenderingHint(RenderingHints.KEY_ANTIALIASING, RenderingHints.VALUE_ANTIALIAS_ON);
final int IMAGE_WIDTH = image.getWidth();
final int IMAGE_HEIGHT = image.getHeight();
final Rectangle2D TRACK;
final Point2D TRACK_START_POINT;
final Point2D TRACK_STOP_POINT;
if (getOrientation() == Orientation.VERTICAL) {
// Vertical orientation
TRACK = new Rectangle2D.Double(IMAGE_WIDTH * 0.315, IMAGE_HEIGHT * 0.1276, IMAGE_WIDTH * 0.05, IMAGE_HEIGHT * 0.7280);
TRACK_START_POINT = new Point2D.Double(0, TRACK.getMaxY());
TRACK_STOP_POINT = new Point2D.Double(0, TRACK.getMinY());
} else {
// Horizontal orientation
TRACK = new Rectangle2D.Double(IMAGE_WIDTH * 0.139, IMAGE_HEIGHT * 0.6285714285714286, IMAGE_WIDTH * 0.735, IMAGE_HEIGHT * 0.05);
TRACK_START_POINT = new Point2D.Double(TRACK.getMinX(), 0);
TRACK_STOP_POINT = new Point2D.Double(TRACK.getMaxX(), 0);
}
// Calculate the track start and stop position for the gradient
final float TRACK_START_POSITION = (float) ((TRACK_START - MIN_VALUE) / (MAX_VALUE - MIN_VALUE));
final float TRACK_STOP_POSITION = (float) ((TRACK_STOP - MIN_VALUE) / (MAX_VALUE - MIN_VALUE));
final Color FULLY_TRANSPARENT = new Color(0.0f, 0.0f, 0.0f, 0.0f);
final float[] TRACK_FRACTIONS;
final Color[] TRACK_COLORS;
// Three color gradient from trackStart over trackSection to trackStop
final float TRACK_SECTION_POSITION = (float) ((TRACK_SECTION - MIN_VALUE) / (MAX_VALUE - MIN_VALUE));
TRACK_FRACTIONS = new float[]{
0.0f,
TRACK_START_POSITION + 0.001f,
TRACK_START_POSITION + 0.002f,
TRACK_SECTION_POSITION,
TRACK_STOP_POSITION - 0.002f,
TRACK_STOP_POSITION - 0.001f,
1.0f
};
TRACK_COLORS = new Color[]{
FULLY_TRANSPARENT,
FULLY_TRANSPARENT,
TRACK_START_COLOR,
TRACK_SECTION_COLOR,
TRACK_STOP_COLOR,
FULLY_TRANSPARENT,
FULLY_TRANSPARENT
};
final LinearGradientPaint TRACK_GRADIENT = new LinearGradientPaint(TRACK_START_POINT, TRACK_STOP_POINT, TRACK_FRACTIONS, TRACK_COLORS);
G2.setPaint(TRACK_GRADIENT);
G2.fill(TRACK);
G2.dispose();
return image;
}
/**
* Returns the image of the title.
* @param WIDTH
* @param HEIGHT
* @param UNIT_STRING_VISIBLE
* @return a buffered image of the title and unit string
*/
protected BufferedImage create_TITLE_Image(final int WIDTH, final int HEIGHT,
final boolean UNIT_STRING_VISIBLE) {
return create_TITLE_Image(WIDTH, HEIGHT, UNIT_STRING_VISIBLE, null);
}
/**
* Returns the image of the title.
* @param WIDTH
* @param HEIGHT
* @param UNIT_STRING_VISIBLE
* @param image
* @return a buffered image of the title and unit string
*/
protected BufferedImage create_TITLE_Image(final int WIDTH, final int HEIGHT,
final boolean UNIT_STRING_VISIBLE,
BufferedImage image) {
if (WIDTH <= 0 || HEIGHT <= 0) {
return UTIL.createImage(1, 1, Transparency.TRANSLUCENT);
}
if (image == null) {
image = UTIL.createImage(WIDTH, HEIGHT, Transparency.TRANSLUCENT);
}
final Graphics2D G2 = image.createGraphics();
G2.setRenderingHint(RenderingHints.KEY_ANTIALIASING, RenderingHints.VALUE_ANTIALIAS_ON);
G2.setRenderingHint(RenderingHints.KEY_FRACTIONALMETRICS, RenderingHints.VALUE_FRACTIONALMETRICS_ON);
G2.setRenderingHint(RenderingHints.KEY_TEXT_ANTIALIASING, RenderingHints.VALUE_TEXT_ANTIALIAS_ON);
final int IMAGE_WIDTH = image.getWidth();
final int IMAGE_HEIGHT = image.getHeight();
final FontRenderContext RENDER_CONTEXT = new FontRenderContext(null, true, true);
if (isLabelColorFromThemeEnabled()) {
G2.setColor(getBackgroundColor().LABEL_COLOR);
} else {
G2.setColor(getLabelColor());
}
final TextLayout LAYOUT_TITLE;
if (getOrientation() == Orientation.VERTICAL) {
// Vertical orientation
// Draw title
// Use custom font if selected
if (isTitleAndUnitFontEnabled()) {
G2.setFont(new Font(getTitleAndUnitFont().getFamily(), getTitleAndUnitFont().getStyle(), getTitleAndUnitFont().getSize()));
} else {
G2.setFont(new Font("Verdana", 0, (int) (0.1 * IMAGE_WIDTH)));
}
if (!getTitle().isEmpty()) {
LAYOUT_TITLE = new TextLayout(getTitle(), G2.getFont(), RENDER_CONTEXT);
final AffineTransform OLD_TRANSFORM = G2.getTransform();
G2.translate(0.0, -0.05 * IMAGE_HEIGHT);
G2.rotate(1.5707963267948966, 0.6714285714285714f * IMAGE_WIDTH, 0.1375f * IMAGE_HEIGHT + LAYOUT_TITLE.getAscent() - LAYOUT_TITLE.getDescent());
G2.drawString(getTitle(), 0.6714285714285714f * IMAGE_WIDTH, 0.1375f * IMAGE_HEIGHT + LAYOUT_TITLE.getAscent() - LAYOUT_TITLE.getDescent());
G2.setTransform(OLD_TRANSFORM);
}
// Draw unit string
if (UNIT_STRING_VISIBLE && !getUnitString().isEmpty()) {
if (isTitleAndUnitFontEnabled()) {
G2.setFont(new Font(getTitleAndUnitFont().getFamily(), 0, (int) (0.07142857142857142 * IMAGE_WIDTH)));
} else {
G2.setFont(new Font("Verdana", 0, (int) (0.07142857142857142 * IMAGE_WIDTH)));
}
final TextLayout LAYOUT_UNIT = new TextLayout(getUnitString(), G2.getFont(), RENDER_CONTEXT);
final Rectangle2D UNIT_BOUNDARY = LAYOUT_UNIT.getBounds();
G2.drawString(getUnitString(), (float) (IMAGE_WIDTH - UNIT_BOUNDARY.getWidth()) / 2f, 0.8875f * IMAGE_HEIGHT + LAYOUT_UNIT.getAscent() - LAYOUT_UNIT.getDescent());
}
} else {
// Horizontal orientation
// Draw title
if (isTitleAndUnitFontEnabled()) {
G2.setFont(new Font(getTitleAndUnitFont().getFamily(), 0, (int) (0.1 * IMAGE_HEIGHT)));
} else {
G2.setFont(new Font("Verdana", 0, (int) (0.1 * IMAGE_HEIGHT)));
}
if (!getTitle().isEmpty()) {
LAYOUT_TITLE = new TextLayout(getTitle(), G2.getFont(), RENDER_CONTEXT);
G2.drawString(getTitle(), 0.15f * IMAGE_WIDTH, 0.25f * IMAGE_HEIGHT + LAYOUT_TITLE.getAscent() - LAYOUT_TITLE.getDescent());
}
// Draw unit string
if (UNIT_STRING_VISIBLE && !getUnitString().isEmpty()) {
if (isTitleAndUnitFontEnabled()) {
G2.setFont(new Font(getTitleAndUnitFont().getFamily(), 0, (int) (0.025 * IMAGE_WIDTH)));
} else {
G2.setFont(new Font("Verdana", 0, (int) (0.025 * IMAGE_WIDTH)));
}
final TextLayout LAYOUT_UNIT = new TextLayout(getUnitString(), G2.getFont(), RENDER_CONTEXT);
G2.drawString(getUnitString(), 0.0625f * IMAGE_WIDTH, 0.7f * IMAGE_HEIGHT + LAYOUT_UNIT.getAscent() - LAYOUT_UNIT.getDescent());
}
}
G2.dispose();
return image;
}
/**
* Returns the image with the given lcd color.
* @param WIDTH
* @param HEIGHT
* @param LCD_COLOR
* @param CUSTOM_LCD_BACKGROUND
* @return buffered image containing the lcd with the selected lcd color
*/
protected BufferedImage create_LCD_Image(final int WIDTH, final int HEIGHT, final LcdColor LCD_COLOR, final Paint CUSTOM_LCD_BACKGROUND) {
return create_LCD_Image(new Rectangle2D.Double(0, 0, WIDTH, HEIGHT), LCD_COLOR, CUSTOM_LCD_BACKGROUND, null);
}
/**
* Returns the image with the given lcd color.
* @param BOUNDS
* @param LCD_COLOR
* @param CUSTOM_LCD_BACKGROUND
* @param IMAGE
* @return buffered image containing the lcd with the selected lcd color
*/
protected BufferedImage create_LCD_Image(final Rectangle2D BOUNDS, final LcdColor LCD_COLOR, final Paint CUSTOM_LCD_BACKGROUND, final BufferedImage IMAGE) {
return LCD_FACTORY.create_LCD_Image(BOUNDS, LCD_COLOR, CUSTOM_LCD_BACKGROUND, IMAGE);
}
/**
* Returns the image of the threshold indicator
* @param WIDTH
* @param HEIGHT
* @return a buffered image of the threshold indicator
*/
protected BufferedImage create_THRESHOLD_Image(final int WIDTH, final int HEIGHT) {
if (WIDTH <= 14 || HEIGHT <= 14) // 14 is needed otherwise the image size could be smaller than 1
{
return UTIL.createImage(1, 1, Transparency.TRANSLUCENT);
}
final int IMAGE_WIDTH;
final int IMAGE_HEIGHT;
if (getOrientation() == Orientation.VERTICAL) {
// Vertical orientation
IMAGE_WIDTH = (int) (WIDTH * 0.0714285714);
IMAGE_HEIGHT = (int) (IMAGE_WIDTH * 0.8);
} else {
// Horizontal orientation
IMAGE_HEIGHT = (int) (HEIGHT * 0.0714285714);
IMAGE_WIDTH = (int) (IMAGE_HEIGHT * 0.8);
}
final BufferedImage IMAGE = UTIL.createImage(IMAGE_WIDTH, IMAGE_HEIGHT, Transparency.TRANSLUCENT);
final Graphics2D G2 = IMAGE.createGraphics();
G2.setRenderingHint(RenderingHints.KEY_ANTIALIASING, RenderingHints.VALUE_ANTIALIAS_ON);
G2.translate(0, IMAGE_WIDTH * 0.005);
final GeneralPath THRESHOLD = new GeneralPath();
THRESHOLD.setWindingRule(Path2D.WIND_EVEN_ODD);
final Point2D THRESHOLD_START;
final Point2D THRESHOLD_STOP;
if (getOrientation() == Orientation.VERTICAL) {
// Vertical orientation
THRESHOLD.moveTo(IMAGE_WIDTH * 0.1, IMAGE_HEIGHT * 0.5);
THRESHOLD.lineTo(IMAGE_WIDTH * 0.9, IMAGE_HEIGHT * 0.1);
THRESHOLD.lineTo(IMAGE_WIDTH * 0.9, IMAGE_HEIGHT * 0.9);
THRESHOLD.lineTo(IMAGE_WIDTH * 0.1, IMAGE_HEIGHT * 0.5);
THRESHOLD.closePath();
THRESHOLD_START = new Point2D.Double(THRESHOLD.getBounds2D().getMinX(), 0);
THRESHOLD_STOP = new Point2D.Double(THRESHOLD.getBounds2D().getMaxX(), 0);
} else {
// Horizontal orientation
THRESHOLD.moveTo(IMAGE_WIDTH * 0.5, IMAGE_HEIGHT * 0.9);
THRESHOLD.lineTo(IMAGE_WIDTH * 1.0, IMAGE_HEIGHT * 0.1);
THRESHOLD.lineTo(IMAGE_WIDTH * 0.1, IMAGE_HEIGHT * 0.1);
THRESHOLD.lineTo(IMAGE_WIDTH * 0.5, IMAGE_HEIGHT * 0.9);
THRESHOLD.closePath();
THRESHOLD_START = new Point2D.Double(0, THRESHOLD.getBounds2D().getMaxY());
THRESHOLD_STOP = new Point2D.Double(0, THRESHOLD.getBounds2D().getMinY());
}
final float[] THRESHOLD_FRACTIONS = {
0.0f,
0.3f,
0.59f,
1.0f
};
final Color[] THRESHOLD_COLORS = {
getThresholdColor().DARK,
getThresholdColor().MEDIUM,
getThresholdColor().MEDIUM,
getThresholdColor().DARK
};
final LinearGradientPaint THRESHOLD_GRADIENT = new LinearGradientPaint(THRESHOLD_START, THRESHOLD_STOP, THRESHOLD_FRACTIONS, THRESHOLD_COLORS);
G2.setPaint(THRESHOLD_GRADIENT);
G2.fill(THRESHOLD);
G2.setColor(Color.WHITE);
G2.setStroke(new BasicStroke(1.0f, BasicStroke.CAP_BUTT, BasicStroke.JOIN_MITER));
G2.draw(THRESHOLD);
G2.dispose();
return IMAGE;
}
/**
* Returns the image of the MinMeasuredValue and MaxMeasuredValue dependend
* on the given color
* @param WIDTH
* @param HEIGHT
* @param COLOR
* @return a buffered image of either the min measured value or the max measured value indicator
*/
protected BufferedImage create_MEASURED_VALUE_Image(final int WIDTH, final int HEIGHT, final Color COLOR) {
if (WIDTH <= 20 || HEIGHT <= 20) // 20 is needed otherwise the image size could be smaller than 1
{
return UTIL.createImage(1, 1, Transparency.TRANSLUCENT);
}
final int IMAGE_WIDTH;
final int IMAGE_HEIGHT;
if (getOrientation() == Orientation.VERTICAL) {
// Vertical orientation
IMAGE_WIDTH = (int) (WIDTH * 0.05);
IMAGE_HEIGHT = IMAGE_WIDTH;
} else {
// Horizontal orientation
IMAGE_HEIGHT = (int) (HEIGHT * 0.05);
IMAGE_WIDTH = IMAGE_HEIGHT;
}
final BufferedImage IMAGE = UTIL.createImage(IMAGE_WIDTH, IMAGE_HEIGHT, Transparency.TRANSLUCENT);
final Graphics2D G2 = IMAGE.createGraphics();
G2.setRenderingHint(RenderingHints.KEY_ANTIALIASING, RenderingHints.VALUE_ANTIALIAS_ON);
final GeneralPath INDICATOR = new GeneralPath();
INDICATOR.setWindingRule(Path2D.WIND_EVEN_ODD);
if (getOrientation() == Orientation.VERTICAL) {
INDICATOR.moveTo(IMAGE_WIDTH, IMAGE_HEIGHT * 0.5);
INDICATOR.lineTo(0.0, 0.0);
INDICATOR.lineTo(0.0, IMAGE_HEIGHT);
INDICATOR.closePath();
} else {
INDICATOR.moveTo(IMAGE_WIDTH * 0.5, 0.0);
INDICATOR.lineTo(IMAGE_WIDTH, IMAGE_HEIGHT);
INDICATOR.lineTo(0.0, IMAGE_HEIGHT);
INDICATOR.closePath();
}
G2.setColor(COLOR);
G2.fill(INDICATOR);
G2.dispose();
return IMAGE;
}
/**
* Returns the image of the glasseffect image
* @param WIDTH
* @param HEIGHT
* @return a buffered image of the foreground glass effect
*/
protected BufferedImage create_FOREGROUND_Image(final int WIDTH, final int HEIGHT) {
return FOREGROUND_FACTORY.createLinearForeground(WIDTH, HEIGHT);
}
/**
* Returns the image that will be displayed if the gauge is disabled
* @param WIDTH
* @param HEIGHT
* @return the disabled image that will be displayed if the gauge is disabled
*/
protected BufferedImage create_DISABLED_Image(final int WIDTH, final int HEIGHT) {
return DISABLED_FACTORY.createLinearDisabled(WIDTH, HEIGHT);
}
//
//
@Override
public void calcInnerBounds() {
final java.awt.Insets INSETS = getInsets();
if (!isFrameVisible()) {
INNER_BOUNDS.setBounds(INSETS.left, INSETS.top, getWidth() - INSETS.left - INSETS.right + 34, getHeight() - INSETS.top - INSETS.bottom + 34);
} else {
INNER_BOUNDS.setBounds(INSETS.left, INSETS.top, getWidth() - INSETS.left - INSETS.right, getHeight() - INSETS.top - INSETS.bottom);
}
FRAMELESS_BOUNDS.setBounds(INSETS.left + 17, INSETS.top + 17, getWidth() - 34, getHeight() - 34);
}
/**
* Returns the rectangle that is defined by the dimension of the component and
* it's insets given by e.g. a border.
* @return rectangle that defines the inner area available for painting
*/
@Override
public final Rectangle getInnerBounds() {
return INNER_BOUNDS;
}
public final Rectangle getFramelessBounds() {
return FRAMELESS_BOUNDS;
}
@Override
public Dimension getMinimumSize() {
return new Dimension(getInnerBounds().width, getInnerBounds().height);
}
@Override
public void setPreferredSize(final Dimension DIM) {
super.setPreferredSize(DIM);
calcInnerBounds();
init(getInnerBounds().width, getInnerBounds().height);
setInitialized(true);
}
@Override
public void setSize(final int WIDTH, final int HEIGHT) {
super.setSize(WIDTH, HEIGHT);
calcInnerBounds();
init(getInnerBounds().width, getInnerBounds().height);
setInitialized(true);
}
@Override
public void setSize(final Dimension DIM) {
super.setSize(DIM);
calcInnerBounds();
init(getInnerBounds().width, getInnerBounds().height);
setInitialized(true);
}
@Override
public void setBounds(final Rectangle BOUNDS) {
super.setBounds(BOUNDS);
calcInnerBounds();
init(getInnerBounds().width, getInnerBounds().height);
setInitialized(true);
}
@Override
public void setBounds(final int X, final int Y, final int WIDTH, final int HEIGHT) {
super.setBounds(X, Y, WIDTH, HEIGHT);
calcInnerBounds();
init(getInnerBounds().width, getInnerBounds().height);
setInitialized(true);
}
@Override
public void setBorder(Border BORDER) {
super.setBorder(BORDER);
calcInnerBounds();
init(getInnerBounds().width, getInnerBounds().height);
}
//
//
// ComponentListener methods
@Override
public void componentResized(final ComponentEvent EVENT) {
final Container PARENT = getParent();
if ((PARENT != null) && (PARENT.getLayout() == null)) {
setSize(getWidth(), getHeight());
} else {
setPreferredSize(new Dimension(getWidth(), getHeight()));
}
calcInnerBounds();
if (getWidth() >= getHeight()) {
// Horizontal
setOrientation(Orientation.HORIZONTAL);
recreateLedImages(getInnerBounds().height);
recreateUserLedImages(getInnerBounds().height);
if (isLedOn()) {
setCurrentLedImage(getLedImageOn());
} else {
setCurrentLedImage(getLedImageOff());
}
setLedPosition((getInnerBounds().width - 20.0 - 16.0) / getInnerBounds().width, 0.453271028);
if (isUserLedOn()) {
setCurrentUserLedImage(getUserLedImageOn());
} else {
setCurrentUserLedImage(getUserLedImageOff());
}
setUserLedPosition(18.0 / getInnerBounds().width, 0.453271028);
} else {
// Vertical
setOrientation(Orientation.VERTICAL);
recreateLedImages(getInnerBounds().width);
recreateUserLedImages(getInnerBounds().width);
if (isLedOn()) {
setCurrentLedImage(getLedImageOn());
} else {
setCurrentLedImage(getLedImageOff());
}
setLedPosition(0.453271028, (20.0 / getInnerBounds().height));
if (isUserLedOn()) {
setCurrentUserLedImage(getUserLedImageOn());
} else {
setCurrentUserLedImage(getUserLedImageOff());
}
setUserLedPosition((getInnerBounds().width - 18.0 - 16.0) / getInnerBounds().width, 0.453271028);
}
getModel().setSize(getLocation().x, getLocation().y, getWidth(), getHeight());
init(getInnerBounds().width, getInnerBounds().height);
}
//
@Override
public String toString() {
return "AbstractLinear";
}
}
